RESEARCH ARTICLE pubs.acs.org/acscatalysis
[Ni(PPh2NBn2)2(CH3CN)]2þ as an Electrocatalyst for H2 Production: Dependence on Acid Strength and Isomer Distribution Aaron M. Appel,* Douglas H. Pool, Molly O’Hagan, Wendy J. Shaw, Jenny Y. Yang, M. Rakowski DuBois, Daniel L. DuBois,* and R. Morris Bullock Center for Molecular Electrocatalysis, Pacific Northwest National Laboratory, P.O. Box 999, K2-57, Richland, Washington 99352, United States
bS Supporting Information ABSTRACT: [Ni(PPh2NBn2)2(CH3CN)]2þ (where PPh2NBn2 is 1,5-dibenzyl-3,7-diphenyl-1,5-diaza-3,7-diphosphacyclooctane), has been studied as an electrocatalyst for the production of hydrogen in acetonitrile. Strong acids, such as p-cyanoanilinium, protonate [Ni(PPh2NBn2)2(CH3CN)]2þ prior to reduction under catalytic conditions, and an effective pKa of 6.7 ( 0.4 was determined for the protonation product. Through multinuclear NMR spectroscopy studies, the nickel(II) complex was found to be doubly protonated without any observed singly protonated species. In the doubly protonated complex, both protons are positioned exo with respect to the metal center and are stabilized by an NHN hydrogen bond. The formation of exo protonated isomers is proposed to limit the rate of hydrogen production because the protons are unable to gain suitable proximity to the reduced metal center to generate H2. Preprotonation of [Ni(PPh2NBn2)2(CH3CN)]2þ has been found to shift the catalytic operating potential to more positive potentials by up to 440 mV, depending upon the conditions. The half-wave potential for the catalytic production of H2 depends linearly on the pH of the solution and indicates a proton-coupled electron transfer reaction. The overpotential remains low and nearly constant at 74 ( 44 mV over the pH range of 6.211.9. The catalytic rate was found to increase by an order of magnitude by increasing the solution pH or through the addition of water. KEYWORDS: electrocatalysis, catalyst, hydrogen production, pendant amine, PCET, potential
’ INTRODUCTION The need for the energy-efficient production and utilization of fuels or energy carriers such as H2 will increase with the utilization of nonfossil energy sources, including solar, wind, and nuclear energy. The production of electricity from many nonfossil energy sources provides motivation for the development of fast and energyefficient electrocatalysts for the storage of electrical energy in chemical bonds. Platinum is the best catalyst for both the production and utilization of hydrogen, written in eq 1 as the forward and reverse reaction, respectively. However, the limited abundance and therefore the high cost of platinum hinders its widespread use as an electrocatalyst1 for common applications or in large scale reactions. Inspiration for the use of nonprecious metal catalysts can be found in hydrogenase enzymes, which operate at low overpotentials and with turnover frequencies for H2 production and consumption on the order of 103104 s1 while utilizing inexpensive metals such as iron and nickel.2,3 2Hþ þ 2e h H2
Bn = benzyl), reaction with H2 (the counterclockwise process in Scheme 1) is thermodynamically favored and forms the doubly nitrogen-protonated nickel(0) complex, Ni(PCy2NBn2H)22þ. This is the first spectroscopically observable complex in the catalytic cycle.5,10 This step is followed by deprotonation, oneelectron oxidation, a second deprotonation, and then a second one-electron oxidation to regenerate Ni(PCy2NBn2)22þ. In the absence of an external base, the H2 addition product, Ni(PCy2NBn2H)22þ, can be observed as three isomers at room temperature, distinguished by the position of the proton in each ligand, either endo or exo with respect to the metal center, as shown in Scheme 2.5,10 Since H2 addition results in double protonation at the amines, these isomers are referred to as endo-endo, endo-exo, and exo-exo to specify the relative location of the two protons. Spectroscopic studies have shown that the endo-endo isomer is the sole product observed from H2 addition at 70 °C,10 but at room temperature, intermolecular proton transfer results in the formation of the
ð1Þ Special Issue: Victor S. Y. Lin Memorial Issue
Electrocatalysts for both hydrogen production and utilization 0 based upon the synthetic molecular complexes Ni(PR2NR 2)22þ 49 have been reported (see Scheme 1). For H 2 oxidation catalysts, such as Ni(PCy2 N Bn2 )2 2þ (Cy = cyclohexyl, r 2011 American Chemical Society
Received: February 20, 2011 Revised: April 7, 2011 Published: April 22, 2011 777
dx.doi.org/10.1021/cs2000939 | ACS Catal. 2011, 1, 777–785
ACS Catalysis
RESEARCH ARTICLE
Scheme 1.0 Proposed Electrocatalytic Cycle for H2 Production (clockwise) or Oxidation (counter clockwise) Using Ni(PR2NR 2)22þ Catalysts
0
of Ni(PPh2NPh2)22þ, protonation, a second one-electron reduction, and then the second protonation. The overall two-electron, two-proton addition is then followed by H2 elimination, which may include essential isomerization of Ni(PPh2NPh2)22þ from exo-exo and endo-exo to endo-endo, as only the latter isomer is expected to be catalytically active by allowing the two protons to gain sufficient proximity to nickel for H2 formation. For most of the H2 production catalysts, the diprotonated Ni(0) species have not been observed because H2 elimination is thermodynamically favored by an estimated 9 kcal/mol for typical catalysts, such as Ni(PPh2NPh2)22þ.11 Ni(PPh2NBn2)22þ is a H2 production catalyst with pendant amines that are more basic than those in Ni(PPh2NPh2)22þ; as a result, the thermodynamic driving force for H2 elimination from the diprotonated Ni(0) form is reduced to 2.7 kcal/mol at 25 °C.8 Ni(PPh2NBn2)22þ was measured to have a turnover frequency for H2 formation that was significantly lower (5 s1) than the analogous catalyst with N-Ph bases, Ni(PPh2NPh2)22þ (350 s1), when the systems were studied under similar conditions.8 Those preliminary studies demonstrated that Ni(PPh2NBn2)22þ was reduced at potentials positive of the Ni(II/I) couple of this complex under acidic conditions. This behavior is consistent with either protonation prior to reduction of Ni(II) to Ni(I) or reduction of Ni(II) to Ni(I) followed by a fast protonation reaction. In either case, the protonation reaction influences the potential at which the electron transfer occurs, thereby indicating that the electron and proton transfer reactions are coupled.1215 In this paper, we report detailed studies of the protonation of NiII(PPh2NBn2)22þ and Ni0(PPh2NBn2)2 and how these protonation reactions influence both the catalytic potentials and rates of electrocatalytic production of H2. Although catalytic rates for this system are not high, the studies reported here provide unique insights into the mechanism of the more active Ni(PPh2NPh2)22þ derivatives.
Scheme 2.0 Reaction of Ni(PR2NR 2)22þ with H2 To Form Ni(PR2NR 2H)22þ As Three Different Isomers, Where Each of the Two Ligands Is Protonated Either Endo or Exo with Respect to the Metal Center
additional isomers. These isomers can be considered the H2 addition product of NiII(PCy2NBn2)22þ or the double protonation product of Ni0(PCy2NBn2)2. For H2 production, the electrocatalytic cycle is thought to proceed as the reverse of the hydrogen oxidation cycle (clockwise rotation in Scheme 1), starting with one-electron reduction 778
dx.doi.org/10.1021/cs2000939 |ACS Catal. 2011, 1, 777–785
ACS Catalysis
RESEARCH ARTICLE
’ RESULTS NMR Studies of the Protonation of NiII(PPh2NBn2)22þ and Ni (PPh2NBn2)2. Addition of p-cyanoanilinium (14 equiv), 0
2,6-dichloroanilinium (12 equiv), or trifluoromethanesulfonic acid (